Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
.X~754
TOY DOLLS ~ID FIGUF~INES
~IAVING 5URF~CE PORTIONS OF
REVERSIBLY CHA21GEAE~LE COLO~
David L. Barker
BACKGROUND OF T~lE IN~ENTION
1. Field of the Invention
The present invention relates to toy dolls and
other figurines. More particularly, it relates to dolls and
other figurines having skins or exterior surfaces repeatedly
capable of reversibly changing color in response to changes
in the p~l of water solutions applied thereto.
2 The Prior Art
The amusement and entertainment derived from toy
dolls, figurines and the like is fundamentally related to
their ability to mimic the physical geometry/ movements/
appearances or functions of the real lie figures which they
represent. Illustrative of such effects presently
incorporated in construction of such toys are "talking
dolls", "weeping dolls", I'sleeping dolls", "walking dolls"
etc.
In particular, dolls have also been made which
simulate topical features such as dolls ~hich change
complexion (see, Eor example, U.S. 2,931, 136 issued April
5, 1960 to E. M. Loewy). Such dolls have chambers
containing two immiscible liquids of differing colors.
Simulation of complexion changes are achieved by altering
37~4
the position of the doll to expose one or the other of the
colored fluids to view. However, such dolls suffer from the
disadvantage that every movement during play causes
alterations in the skins' features.
Other dolls have been provided in the past which
reversibly simulate changes in skin or surface color or
condition by the provision of a series of removably
detachable ele~ents adapted to be attached to the doll (see,
for exa~nple, U.S. 2,959,~91 issued November 15, 1960 to H.
E. Barnett, et al). A wide variety of skin conditions,
ailments and diseases can be simulated which are not subject
to random change with alteration of the doll's position.
However, a plurality of detachable elements are needed which
by virtue of their detachability are subject to being lost
or misplaced.
Still other dolls are known in the art which
reversibly simulate changes in skin color which do not
require a plurality of detachable elements U.S. 2,921,407
~issued January 19, 1960 to C~ A. Wagner, et al), discloses
dolls which are able to simulate sunburning. Such dolls
operate through incorporation of certain phototropic dyes in
appropriate transparent bodies or coatings. ~lowever, such
dolls suffer from three principal disadvantages. First,
ultraviolet radiation ls usually required to effectuate the
color change in the doll's skin such as by exposure to
sunlight~ While certain artificial light sources can
provide the necessary ultraviolet light to effectuate the
75~
change in the color of the doll's sk;n, these artificial
li~ht sources are not always readily available and may
actually be dangerous to use. seconcl, the color chanye
usually ta~es several minutes of exposure to sunliyht to
complete. Finally, the phototropic dyes which are c~isclosed
are able to sirnulate only a limited number of colors.
Given the state of the doll art as described above,
there is a continuing need for new toy dolls, and other
figurines which have surfaces repeatedly capable of
reversibly changing color without the need for prolon~ed
exposure to sunliyht. Accordingly, it is an object of the
present invention to provide a novel toy or a doll having a
surface portion which is reversibly chan~eable in color.
It is another object of the present invention to
provide toys, dolls and figurines capable of simulating skin
conditions without the need for removably detachable
elements.
It is another object of the present invention to
provide toy dolls and other fiqurines which can display
changing slcin colors or conditions which do not change upon
alteration of the position of the doll or other figurine.
It has been surprisin~ly discovered that the above
objects can be realized by toy dolls and figurines employing
a surface coating of 3 naterial, in combination ~ith a film
forming polymeric carrier, that reversibly changes color in
response to the pH of aqueous solutions applied to them.
-- 3 --
S4
SUMMARY OF THE INVENTION
The present invention relates to toy dolls and other toy figurines
which have skin or exterior surfaces repeatably capable of rever~lbly c~ang-
ing color.
The invention provides an animate like figurine repeatedly ~apable
of reversibly changing color, comprising a body having an outer surface to
at least a portion of which has been applied a first layer containing pH-
indicating material, adhered to at least a portion of the outer surface, that
is adapted to reversibly change color in response to changes in the hydrogen
ion activity of water solutions applied thereto.
In the most preferred embodiment, toys comprise a body having a
resilient skin to which has been applied three layers. The first layer seals
the skin to provide a continuous adherent surface. The second layer applied
over the first layer and attached thereto is adapted to change color in
response to changes in the hydrogen ion activity (pH) of water solutions
applied to the second layer. A third, water permeable layer is super-
imposed over the second layer to protect the second layer from abrasion.
BRIEF DESCRIPTION OF THE DR~WINGS
Figure 1 is a perspective view of a doll embodiment of the present
invention;
Figure 2 is a rear elevational view of the doll embodiment;
Figure 3 is a partial vertical sectional view taken along lines
3-3 of Figure 2;
Figure 4 is a greatly magnified sectional view of the coated skin
taken along lines 4-4 of Figure 2;
Figure 5 is an enlarged sectional view of the coated skin taken
along lines 5-5 of Figure 4;
Figure 6 is a partial sectional view showing another embodiment
of the invention; and~
Figure 7 is an enlarged sectional view of another embodiment of
the coated skin similar to that shown in Figure 4.
--4--
.~
~2~S~
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
. .
The present invention relates to toys, dolls and
figurines which are reversibly adapted to chan~e color in
response to chanyes in the hydrogen ion activlty o a~ueous
solutions applied to them. For convenience, the followiny
detailed description is set forth with par-ticular emphasis
on toy dolls. It should be understood, however, that the
présent invention contemplates other amusement
devices including animate-like figurines of, for example,
creatures such as frogs, alligators, space monsters,
chameleons and the like.
Referring now to the drawings, and to FIG. 1 in
particular, there is shown the general confic~uration of a
doll having a body 10, a pair of arins 12, a pair of legs 14,
and a head 16. The doll is depicted as wearing a dress 18
as well as a diaper 20. A portion of the doll's skin
incorporates the reversibly chan~eable color feature 22 of
the present invention. As seen more clearly in FIG. 2,
which-is a rear view of the preferred doll embodiment, the
present invention is shown as including a random array o
rash dots 24.
As can be seen more clearly in FIG. 3, the
preferred embodiment of the present invention comprises a
converltional wetting doll which is well known in the art.
FIG. 3 is a partially cut-away sectional view along lines
3-3 of FIG~ 2. The head 15, is rotably attached to the body
10. Rotation of the doll head 15 is allowed by the doll
~287S4
head having a grooved neck collar 56 which encircles a
flange 55 forming an integral part o~ the doll body. This
construction permits rotational movernent oE the head
relative to the body. A mouth 34 forms an opening in~o the
head, and a short orifice tube 36 projects inwardly from the
mouth. The free end 37 of the tube 36 is rotably inserted
into a first end 40 of an elonyated body tube 38. As
illustrated~ the inside diameter of the tube 38 exceeds the
outside diameter of the oriEice tube 36. This construction
permits unrestricted rotation of the doll head relative to
the body. A plug 42 is inserted into the second end 41 of
the body tube 3S, and it has an outer diameter slightly less
than the body tube such that a tight fit results. The plug
serves to restrict or to impede the flow of any aqueous
solution through the tube. A passage 44 in the plug
provides a discharge opening 45 in the posterior of the
dollls body 10.
~ bottle 28 is used for introducing an aqueous
solution into the doll. As depicted in FIG. 3, a bottle cap
30 which terMinates in a tapered nipple 32, is insertable
into the doll's mouth 3~.
Typically, the body cavity is filled ~ith stuffing
of any suitable material 5~ such as polyester, polyurethane
Eoam or the like. The d~ll body 10 has a resilient,
flexible skin 48 of any conventional suitable material such
as polyurethane or vinyl plastisols.
-- 5 --
~Z1375~
The doll can wear a 2-ply diaper 50, forrned of a
first-ply Ol layer 52 and a second ply or layer 54. rrhe ply
closest to the doll's skin 52 is water absorbent and
typically is made of cellulosic material such as paper,
althouyh an open-cell foam also is suitable. The ply 52
serves to receive aqueous solutions which exit frorn the body
tube 38 through the discharge openin~ 44, and to evenly
distribute more or less, the aqueous solution over that
coated skin portion 22 of the doll's skin 48 which
incorporates the present invention's feature. Addtionally,
the water-absorbent ply 52 allows longer contact periods
between the aqueous solution and the coated skin portion 22.
A second ply 5~ is bonded to the paper ply and it is water
impermeable~ The ply 54 is made from such conventionally
suitable materials as plastic (e.g., polyvinyl chloride).
It should be recognized that FIG. 3 shows just one
manner of those known in the art in which aqueous solutions
are adapted to pass from the doll mouth to the doli
posterior and means for distribution of the aqueous solution
thereover.
Before proceeding with a detailed description of
the doll's surface which is capable of changing color, a
brief reference will be made to FIG. 6 whicll illustrates
another embodiment of a conventional wetting doll. This
embodiment does not require a diaper to assist the
distribution of aqueous solutions around the coated regicn.
FIG. 6 is a partially cut away sectional view which is
7S4
somewhat similar to that shown in FIG. 3. The orifice tube
36 is rotably insertable into the first end 82 oE the second
type of body tube 80. The body tube ~0 has a tapered region
5~ which reduces the inside and ou-tside diameters of the
body tube. A second end 86 of the tube terrninates proximate
the doll's posterior. The reduced diameter oE the body tube
80 serves to restrict liquid flo~ and thus the liquid flow
rate through the tube. The second end 86 of the tube is
connected to a liquid reservoir 50 which is formed by a
liner 62 attached to the inner surface of the skin 48 by
appropriate rneans. As illustrated, the reservoir 60 is
located between the doll's skin and the body fill ~aterial
46. A plurality of apertures 64 are provided in the doll
skin 48 on the region of the doll's posterior. The
reservoir serves to reduce liquid flow and to evenly
distribute rnore or less, the liquid about the region
simulating excretion of body fluids. The body fill liner 62
is water impermeable so as to prevent the liquid from
soaking into the body fill material 46. The apertures 64
permit the release of the liquid from the liquid reservoir
60 to the outer surface of the doll's body. The skilled
artisan can easily adjust the size and number of these
apertures to achieve any desired liquid flow rate. FIG. 6
shows just another manner of tnose many kno~n in the art in
which dolls are adapted to pass aqueous solutions frorn the
doll mouth to the doll posterior ancl means for distribution
of the aqueous solution thereover.
- ~Z~il759~
A. _ se Coat La~er
Referrinc3 now to ~IG. ~, there is shown a ~reatly
enlarged sectional view taken along 4-4 of FIG. 2. In FIG.
there is shown a first, continuous layer Z6 or "base co~t"
as used hereirl which is an essential elemen~ of ~he most
preFerred embodiment oE the present invent:ion. The base
coat is shown adhering to the doll skin 48. Such a base
coat layer provides a ~Iprimer~ or an adherent surEace to
which can be applied the color coat which is described more
fully below. Such a base coat layer is particularly
desirable when the doll's exterior surface is abhesive in
nature (e.g., porcelain). When the doll's skin or external
surface is made oE such conventional synthetic materials as
vinyl acrylate, the base coat additionally serves to seal
the skin and thereby to reduce the undesirable migration of
plasticizers from the vinyl n~aterial of the skin into the
color layer. In a preferred embodiment, the base coat layer
is at least about 1 mil in thickness. Thus, it should be
recognized that the thickness of the elements in FIG. 4
depict only relative differences rather than absolute. Most
preferably, the base coat is at least about 2 mils in
thickness.
The base coat comprises a mixture of film-forming
polymeric ~aterials which are hydrophobic. An example of
naterial useful herein as base coat materials is a mixture
~Z~37S4
of (1) polymethyl methacrylate, e.g., having a Brookfield
viscosity of about 700-1400 centipoise at 35~ solids in
methylethyl ketone; and~ (2) vinyl acetate/chloride
copolymer, e.g., having a viscosity of about 50-100
centipoise at 10% solids in methylethyl ketone and wherein
the weight ratio of polymethyl methacrylate to vinyl
acetate/ vinyl ch]oride is from about 2.0:1 to 2.5:1. Other
acrylic polymeric materials can be used such as polybutyl
methacrylate. Similarly, other vinyl chloride polymeric
materials are usefully employed such as polyvinyl chloride
and polyvinylidene chloride.
Typically, the mixture of polymeric material is
applied to the doll's skin in solution with suitable
diluents such as methylethyl ketone or methylisobutyl
ketone. After application to the skin by spraying, for
example, the diluent(s) is allowed to dry under a~bient
conditions to form the base coat of suitable thickness.
Drying can be expedited by employin~ temperatures of about
100F
-- 10 --
:~L128~S~
B. Color Lay~
In EIG. 4 there is shown a secor-cl layer 68 which is
repeatedly capable of reversibly changing color. The second
layer is adapted to cllan~e color in response to change~ in
the pH of water solutions applied to the second layer. This
second layer, or "color layer" as used herein, is shown
adhering to the base coat layer. In the embodiment shown in
FIG. 4, the color layer 68 is discontinuous, i.e., comprises
separate area. When generally circular in configuration,
these areas are called rash dots. Such rash dots 24 are
shown in FIG. 2. As detailed in FIG. 4, such rash dots
comprise color materials in a matrix of film-forming
polymers which are both flexible and hydrophilic. A dotted
array 26 of such rash dots 24 is shown in FIG. 2. Such a
dotted array can be either random or organized.
FIG. 7 shows another embodiment of the color layer
68. In this embodiment, the reversibly changeable feature
comprises a continuous layer of more or less even thickness.
Suitable color materials for use in the color layer
are those substances which change color in response to the
hydrogen activity of aqueous solutions applied to them,
i.e., typical pH or "acid-base" indicators. A wide variety
of such materials are known and their properties, e.g./
color and pH tr~nsition range, are disclosed in "Pil and
Electro Titrations", by I. M. Kolthoff and H. A. Laitinen,
John Wiley & Sons, Inc. 1941, P. 29 and "Acid-Xase
Indicators", I. M. ~olthoff and C. ~osenblumm, Chapter 5,
~.~2~3750~
the MacMillan Company, 1936. Some suitable materials are
given in TABLE I below.
T A B L E
ACID-BASE I~DICATORS
Transition olor Chan~e
Common Name Range (~H~ Acid Base
Methyl violet 0.5-1~5 yellow blue
~Thymol Blue 1.2-2.8 red yellow
8.0-9.6 yellow blue
Methyl yellow 2.9-4.0 red yellow
Methyl orange 3.1-4.4 red yellow
Bromcresol green 3.8-5.4 yellow blue
Methyl red 4.2-6 3 red yellow
Chlorophenol red 4.8-6.4 yellow red
Bromthymol blue 6.0-7.6 yellow blue
Phenol red 6.4-8.0 yellow red
Neutral red 6.8-8.0 red y~llow/
orange
Cresol purple 7.4-9.0 yellow purple
1.2-2.8 red yellow
Phenolphthalein 8.0-9.6 colorless red
Thymolphthalein 9.3-10.5 colorless blue
Alizarin yellow 10.1-12.0 colorless violet
Preferred reversible color indicating materials are
solid at room temperatures (e.g., 25 C.) although liquid
materials can be used. More preferred materials are
colorless below their pH transition range. Specific,
preferred reversible color materials include chloropheno~
red, phenolphthalein, and phenol red. Best results are
achieved using phenolphthalein as the acid-base indicator.
2~3754
The reversible color material of the color layer or
rash dot is essentially matrixed in a mixture of filrn-
forminq hydrophilic material. ~ first polymeric componellt
of the matrix enables the color layer or rash dot to adhere
to the base coat. Suitable such polymers or "bindersl'
include cellulose acetate propionate and cellulose acetate
butylate. For best results, cellulose acetate propionate is
employed as the film-forming binder polymer. The weiyht
ratio between the reversible color material to binder
polymer ranges froM about 0.6:1 to 2.6:1. Optionally, the
binder additionally includes a plasticiæer to improve the
color layer flexibility and to improve film clarity.
Suitable optional binder coat plasticizer materials include
butyl benzyl phthalate, diethyl phthalate, dibutyl
phosphate, dioctyl phthalate and tricresyl phthalate. If
; present, such optional binder materials comprise from about
1% to 5% of the first polymeric component of the color coat
layer.
A second polymeric component of the color coat
layer matrix material is a second film-forminy polymer which
is highly water absorbent and is referred to herein as a
wicking component. The wicking component serves to
accelerate the transport of water to the reversible color
material. Suitable wickiny component materials include
hydroxyethyl cellulose, hydroxypropyl cellulose, sodium
carboxymethyl cellulose and fused silicon dioxide. The
preferred material for the wicking component is hydroxyethyl
1~2~7S4
cellulose. The weight ratio between the binder component
and the wicking component ranges from about 2:1 to 17:1.
In a highly preferred embodimenk seen more clearly
in FIG. 5, the rash dot 24 comprises agglomerates 70 o
smaller particles 72 in the matrix of ~ilm-ormin~ polymers.
These smaller particles 72 are the capsules of microencap-
sulated reversible color materials that are distributed
throughout the rash dot. Provision of the color material in
microencapsulated form unexpectedl`y and greatly extends the
number o cycles through which the color change can be
reversed.
Since the color materials used herein are at least
partially water soluble, some of the color material is
leached out by the applied aqueous solutions during color
reversals. Encapsulation of the color material markedly
reduces the amount of color material solubilized by the
contacting aqueous solutions and thus greatly extends the
number of cycles of color reversal provided by a given
amount of color material.
Conventional chemical or mechanical microencap-
sulation methods are used to microencapsulate the acid-base
indicating reversible color material. Such techniques are
very well known. See, for example, "Microencapsulation~ by
C. E. Anderson et al, Management Reports, Inc. (1963).
Typically, microcapsules' nuclei of reversible color material
will range in diameter of from about 75 to 250 microns. Wall
thickness of the microcapsules will range from about 1 to 5
microns.
- 14 -
., .
~lZ8754
,
Generally, in conventional chemical microencap-
sulation methods, a hydrophillc colloid which is to become
the cell wall of the capsules is simply dispersed in watsr.
To this dispersion is added a slurry of reversible color
material in an oil which is imrniscible in water. The
mixture is agitated to form a colloid-oil/reversible color
material-water emulsion. Next, a coacervating salt is added
to the emulsion. The effect of the salt is to render the
colloid less soluble in ~ater; consequentlyj a fluid sheath
of colloid comes to surround the oil/reversible color
material droplet. This is frequently referred to as
gelation.
During all of the foregoing steps the ternperature
of the system is carefully maintained above the melting or
solidifying point of the colloidal material. Consequen-tly,
to complete the capsules' formation, the temperature of the
system needs only to be reduced to the point where the
colloidal material becomes solid. The temperature is
lowered by adding to the system additional cool coacervation
salt aqueous solution.
It is important that the capsules remain porous to
allow transport of aqueous solutions to contact the
reversible color material in the nuclei of the capsule. The
porosity of tihe capsule wall can be controlled in ~;nown
manner by manipulating the rate at which the wall material
gels. Wall pores will be relatively small if the gelation
step is performed rapidly. Conversely, larger pores will be
~12875~
formed in the capsule wall if the ~elation step is
relatively slow. By varying the relative arnounts of colloicl
and oil and the size of the oil droplets, capsu]es with
tailored wall thickness are obtained.
Suitable oils materials for the microencapsulation
process are immiscible in water (i.e., soluble in water to
not more than 0.05% by weight at 25C.) and including for
example, cottonseed oil, corn oil, soybean oil~ coconut oil,
castor oil and olive oil. Preferred oils are intermediate
petroleum oils like hexane, cyclohexane and the like.
Suitable colloidal materials are hydrophilic and
gelable as well as inert to the reversible color material
and other capsule constituents. Useful colloids include
gelatin, alginates, casein, starch, pectins, carboxymethyl
cellulose, Irish ~oss and gum arabic. Suitable coacervation
salts have cations such as sodium potassium, ammonium and
lithiu~ and anions of sulfate, citrate, tartrate, acetate
and chloride. Specific examples of coacervation salts
include sodium sulfate, sodium citrate, sodium chloride,
potassium sulfate, potassium citrate and potassium chloride.
The hues of color realized by the present
reversibly changeable color feature of the present invention
are in1uenced by two actors. ~irst, the ratio of color
rnaterial to matrix material influences the color's hue.
When relatively more color material is incorporated into the
matrix, stronger hues are realized. Conversely, when lower
ra~ios of color material to total matrix materials are
- 16 -
87S4
employed, weaker hues are realized. Similarly, the color
hue is influenced by the thickness of the color layer. For
a given color Material to total matrix ~aterial ~1eiyht
ratio, the thicker the color layer (or in the preferred
embodiment, the rash dot) the stronger the hue.
When microencapsulated color material is used in
the color layer, the weight ratio of microencapsulated color
material to the binder component o~ the matrix polyrneric
material is again from about 0.6:1 to 2.6:1.
C. Top Coat Layer
In FIG. 4 there is shown a top coat layer 7~ which
also is an essential element of the most preEerred embodi-
ment of the present invention. The top coat comprises a
thin film over the color layer that serves to provide
abrasion resistance to the portion oE the doll skin
incorporating the present invention. Also, without such a
top coat layer, the color layer could be responsive to skin
moisture upon handling of the doll. Additionally, without
the top coat layer, the capsules of microencapsulated
reversible color material could be subject to rupture during
normal handling ~hich leads to both color bleeding and
greatly reduced cycle life. The top coat is applied over
the color coat and adheres thereto. Since aqueous solutions
nust penetrate the top coat layer in order to effectuate
changes in the reversible color ~aterial of the color layer,
it is essential that the top coat layer be permeable to such
aqueous solutions. However, the top coat layer must be
- 17 -
`` 1~2~37S~
relatively insoluble to such aqueous solutions. Otherwise,
the top coat layer woulc] be washed away upon use.
Top coat thickllesses are typically less than 1 mil.
It is, of course, desirable that the top coat be
transparent.
The top coat layer comprises the same two film~
forming polymer components as does the color layer matrix
material~ A first~ or "binder" water-insoluble hydrophilic
film-forming material(s) enables the top coat layer to
adhere to either the rash dots of the color layer or to the
base coat layer between the discontinuous regions of the
color layer. Suitable materials for the binder component oE
the top coat layer are those also useful as the "binder"
component in the base coat layer e.g., cellulose acetate
propionate or cellulose acetate butyrate, or the like. A
second, or "wicking" component of the top coat layer
provides the required water absorbtivity to render the top
coat layer sufficiently ~ater permeable. Suitable materials
for the wicking component of the top coat layer are those
also useful as the wicking component of the base coat layer,
e.g., hydroxyethyl ethers of cellulose. In the top coat
layer, the weight ratio of the binder component to the
wicking component should be from about 3:1 to about 7.5:1.
Better results are obtained when the wei~ht ratio of bincler
component to wicking component is from about 3 1 to 5:1.
~z~3754
-
Resins of suitable polymeric materials are simply
dissolved in suitable solvent(s). Thereater~ the solution
is applied such as by spraying over the color layer and
allowed to dry at ambient conditions.
Optionally, each of the three layers can in~lude a
"skin-toner" which is a material that helps the layers match
the doll skin in simulated pigmentation. Such skin-toner
materials thus enable the reversible changing feature of the
present invention to be less conspicuous by allowing the
io layers to blend in with the skin by virtue of the matched
pigmentation. Suitable skin-toner materials include "Dayglo"*
pigments and Dayglo Soluble Toners marketed by Day-Glo Color
Corporation.
Another component which can be included in any of
the layers of the present invention is a n flattener"
material. Such flattener materials reduce the gloss which
can be exhibited by the layers of the present invention.
Suitable materials for such flatteners are pyrogenic or
"fumed" silicon dioxide such as is described in British
patents 987,301 and 1,167,173,
* denotes Trademark
- 19 -
~.~.2~375~
Invention Use
Typically, a child would fill the bottle 2~ with
water and add alkaline ~aterial in suitable form (e.g.,
prepared tablets) sufEicient to raise the pH of the
resulting aqueous solution to in excess of 10. A~ter the
bottle cap 30 is secured to the ~ottle, the bot~le is sha~en
with sufficient vigor for sufficient time so as to allo~ the
complete dissolution of the added alkaline material.
Thereafter, the nipple 32 of the bottle cap 30 is inserted
into the aperture formed by the mouth 34 in the doll's head.
~he alkaline aqueous solution flows into the body tube 38 by
gravity. After being discharged through the discharge
opening 44, the aqueous solution is more or less uniformly
distributed over the treated s~in por-tion incorporating ~he
reversible color feature of the present invention. The
alkaline aqueous solution quickly penetrates through the top
coat layer into the rash dots. There, the aqueous solution
penetrates the porous cell walls of the capsules and
contacts the reversible color material contained in the
nuclei. The contact between the al~aline aqueous solution
and the microencapsulated reversible color material causes
the color material to change color in response to the
hydro~en ion acti~ity of the contactin~ aqueous solution.
The color chan~e so caused is manifested within a few
seconds and simulates the appearance of a diaper rash.
- 20 -
~2~375~
To simulate alleviation of the diaper rash
condition by reversibly chan~inc~ the color of the rash dot
to its ori~inal color or colorless condition, the alkaline
water-impre~nated diaper is first rel~oved. Thereafter, an
acidic aqueous solution or "lotion" having a pEI of less than
5 is applied to the portion of the doll skin incorporating
the reversibly chanyeable color Eeature of the present
invention. The lotion is prepared by mixing sufficient
quantities of acid material so as to achieve a solution pH
of about 4. The lotion can be applied to the doll skin
using a simple open-celled plastic foam pad, designated
generally by nu~eral 76. Upon swabbin~ the treated skin
portion with acidic aqueous solution, the acidic aqueous
solution quickly penetrates the top coat layer and enters
into the nuclei of the r~licroencapsulated reversible color
material. The reversible color material again responds to
changes in the pH or hydrogen ion activity of the aqueous
solution applied thereto. The contact between the rever-
sible color material and the low pH aqueous solution causes
the reversible color material ~o revert back to the ori~inal
colored or colorless condition that obtained previous to the
contact with the alkaline solution. The reversion which
occurs within a few minutes of exposure to the acidic water,
simulates a "curative" effect. This action is repeatable
with no detectable chan~e in functional characteristics
bein~ noted after several dozen cycles.
_ ~1
Z8~S4
The reversibly changeable color features of the
present invention are illustrated by the following examples:
EXAMPLE I
A. Base Coat Layer
The followiny composition is prepared:
Component Weight
Polymethyl methacrylate resinl 12
Vinyl acetate/vinyl chloride co-polymer 6~
Methylisobutyl ketone 21%
Methylethyl ketone 52~
Cellosolve acetate3 8.97%
Flattener4 .03%
100~
1. Acyloid A-101 (marketed by Rohm ~ Haus) having density
of 7.9 lb./gal. and a Brookfield viscosity (25C) of
between 700-1400 cp. at 40% by weight resin in methyl-
ethetyl ketone; a solubility parameter of 9.4 and a Tg C
o~ 105C.
2. A high molecular weight ~i.e., a Brookfield viscosity of
200-400 cp... at 17% solution o resin in 70:30
methylethetyl ketone: ioluene at 25C) vinyl chloride-
vinyl acetate copolymer comprisinq approximately 89~ by
weiqht polyvinyl chloride marketed by Union Carbide
Corporation as "fiakelit VYNS".*
3. A retarder solvent, i.e., an optional additive to
decrease the volatility of the solvent.
* denotes Trademarks
- 2~ -
.._.
~L~Z157S4
. An optional component to reduce gloss such as OK-~12
marketed by DeGussa, ~nc. and which is a fumed silicon
dioxide.
Resins of the plastic components and the retar~er
solvent as well as the flattener are dissolved into the
ketone solvents by mild agitation for 15 minutes.
0.05 grams of the base coat are sprayed OlltO the
desired portion of a doll skin comprising about 5 square
inches and allowed to dry by solvent evaporation at room
temperature for 15 minutes. A film approximately 1.5 mil is
formed adhering to the surface of the doll s~in.
B. Color Layer
Thereafter, the followiny compositions are
prepared:
1. Binder Component Weight
Cellulose acetate propionate 7O5
Plasticizer (butyl benzyl
phthalate) 2.0%
Anhydrous isopropyl alcohol ~79~O
Color 0.01%
; Deionized water q.s.
* 100%
marketed by Eastman Chemical Products r Inc~ as
CAP-504
_ 23 ~
~.lZ~375~
The deionized water, color and isopropyl alchohol
are first mixed. Thereafter, the cellulose acetate
~ropionate and plasticizer are slowly added with viyorous
agitation and the agitation is continued until the cellulose
acetate propionate and plasticizer are coMpletely dissolved.
The ~ollowing composition is prepared:
2. Wicking Component Wei~
*
Hydroxyethyl cellulose 8%
Plasticizer (dioctyl butyl
phthalate) 3~
Sodium benzoate 0.5%
Deionized water q s.
100
*Natrosol 250 LR marketed by Hercules, Inc.
The hydroxyethyl cellulose, plasticizer and the
sodium benzoate are each added slowly to the water using
vigorous agitationO Agitation is continued until the
hydroxyethyl cellulose is completely dissolved.
- 2~ -
~Z87S0~L
Thereafter, the following color composition is
prepared:
Component Weiyht ~
Binder Component 70%
Wicking Component 18
Microencapsulated phenolphthalein 125
100
marke-ted by Appleton Papers, Inc., Capsular
Products Division and haviny a particle size of
approximately 100 microns and a wall thickness of
approximately 1 mi1.
The color composition is prepared by slowly adding
the cellulose component to the binder component as prepared
above using vigourous agitation. Thereafter, the micro-
encapsulated phenolphthalien is slowly added using mild
agitation.
Rash dots of about 0.25-0.5 inch in dia~eter are
hand made by painting the color composition prepared above
using approximately 0.06 g. of the color composition. The
rash dots are allowed to dry by solvent evaporation at room
temperature for 15 minutes. A dot approximately 4 mil in
thickness is produced.
- 25 -
'112B754
C. Top Coat Layer
The following composition is prepared:
l. Binder Component _eight ~
Cellulose acetate butyrate 7.S%
Anhydrous isopropyl alcohol 80~0
Color 0.03
Deionized water ~s.
100%
*
CAB 553 marketed by Eastman Chemical Products, Inc.
The cellulose acetate butyrate is slowly added to
the mixture of isopropyl alcohol, color and deionized water
using vigorous agitation. Agitation is con-tinued until the
cellulose acetate butyrate is completely dissolved.
The following composition is prepared:
2. Wicking Component h'eight %
Hydroxyethyl cellulose 8%
Plasticizer (dioctyl butyl
phthalate) 2~
Sodium benzoate 0~5%
Distilled water q.s.
100%
*
Natrosol 250 LR marketed by ~Iercules, Inc.
Such a wicking agent is prepared in a similar
manner to the wicking component o the color layer described
above.
- 26 -
1~2~37S~
Thereafter, the following top coat composition is
prepared.
Component Weight
Binder Component 7~
Wicking Component 5%
Diacetone alcohol ~.s.
100%
Such a top coat composition is prepared by simple
mixing of two components with mild agitation. The top coat
layer is produced by spraying the top coat composition over
the entire area of the doll skin having the reversibly
changeable color feature of the present invention. A
continuous film of under 1 mil in thickness is produced when
approximately 0.065 g. is used to coat approximately 5
s~uare inches~ After application by spraying, the top coat
layer is allowed to dry by solvent evaporation for 15
minutes at ambient conditions.
The doll so prepared exhibits a simulated diaper
rash when that portion of the doll skin incorporatin~ the
color feature of the present invention is contacted with a
water solution having a pH of 10. ~he color change occurs
only a few seconds ater contact with the high pH water.
- 2~ -
~lZ87S~
EX~MPLE II
A. Base Coat Layer
A base coat layer composition as in Example I is
prepared. 0.05 g. of the base coat ~re sprayed onto the
desired portion of the slcin oE a doll as shown in FIG. 3
cornprisinc3 about 5 square inches and allowed to dry by
solvent evaporation at room temperature for 20 minutes. A
film approximately 1 mil is formed adhering to the surface
of the doll skin.
B. Color Layer
Thereaf-ter, the following color layer composition
is prepared.
Amount Component Weight %
90.5g Methyl alcohol 78.70%
2.0 Butyl benzyl phthalate1.74%
7.5 Cellulose acetate propionate 6.52%
5.0 ~ydroxypropyl cellulose4.35%
10.0 Microencapsulated pheonol red 8.69%
100%
~arketed by Eastman Chemical Products, Inc. as CAP-504
_
The methyl alcohol and ben~yl butyl phthalate are
first mixed. Then, with vigorous agitation, the cellulose
propionate is slowly added. The agitation is continued
until the cellulose acetate propionate is completely
dissolved. Vigorous agitation is continued while the
- 2~ -
~lZ~37~
hydroxypropyl cellulose is added until it is dissolved.
Then, the encapsulated phenol red is added using mild
ac3itation.
Rash dots 0.25-0.5 inch in dial~eter are made by
painting the color layer composition as in Example I except
that dots approximately 2 mil in thickness are prepared by
using less color layer composition per dot. After dryiny
for 20 minutes, several dots randomly chosen are hand
painted a second time and are allowed to dry. These dots
range in thickness from 4 to 8 mil.
C. Top Coat Layer
Thereafter, the following top coat layer com-
position is prepared:
Amount Component Wei~ht %
9Q.5g Methyl alcohol 86.20%
2.0 Butyl benzyl phthalate1.90%
7.5 Cellulose acetate propionate - 7.14
5.0 Hydroxypropyl cellulose4.76
100%
marketed by Eastman Chemical Products, Inc. as CAP-504
The top coat layer composition is prepared in a
similar manner as the color layer composition except for the
addition of the encapsulated reversible color material.
The top coat layer is applied by spraying the
composition prepared as desired above and by solvent drying
for 20 minutes at ambient conditions.
- 29 -
~28754
The wetting dolls having the reversibly changeable
feature of the present inVentiOIl prepared as described above
exhibits a bright red color when ~Ifed~ with an aqueous
solution having a pl-i of 8.5 or above. The color change
occurs approxilnately 30-60 seconds aEter being "fed~' with
the high pH aqueous solution.
When the portion of the doll's skin possessing the
color feature of the present invention is thereafte'r swabbed
with a foam pad carrying an aqueous solution having a pEI of
about 3, the color disappears after about 10 seconds as the
pH material reverts back to a colorless condition. If
dried, the skin remains colorless.
Dolls exhibitin~ substantially similar reversibly
changeahle color features are realized when in the Example
II color layer corliposition the solvent methyl alcohol is
replaced with an equivalent amount of ethyl alcohol or the
diluent comprising isopropyl alcohol and water in a weight
ratio of alcohol to water of about 9:1.
- 30 -
~Z~3754
EXAMPLE III
The skin portion of a wetting doll having the
structure of FIG. 6 is coated with a base coat and color as
in Example II. Then, the following top coat layer
composition is prepared:
Component Weight %
*
Cellu'ose acetate butyrate4.51
Anhydrous isopropyl alcohol72.20~
. Deionized water 19.01%
Butyl benzyl phthalate 1.79%
Fumed silicon dioxide 2.59
(Cab-O-Sil***: grade M-5)
100%
.
* CAB-553 marketed by Eastman Chemical Products, Inc.
** A pyrogenic silica (Cabot Corp.) having a particle
diameter between 0.0~1 and 0.03 microns.
The above ingredients were blended together and
placed in a ball mill and milled for 72 hours.
Then, about 10% by weight diacetone alcohol as an
additional diluent is added to the top coat layer prior to
use using mild agitation. Thereafter, the top coat layer is
prepared by spraying the top coat composition onto the doll
skin and allowing it to dry~
*** denotes Trademark
. - 31 -
